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Using a Nitrate Specific Ion Electrode to Determine Stalk Nitrate–Nitrogen Concentration

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The end-of-season stalk NO3 test has been used to determine N sufficiency in corn (Zea mays L.). Nitrate concentration is commonly determined with flow-injection analysis (FIA), which is accurate but uses hazardous chemicals and is time-consuming. Use of a simpler method of NO3 determination, such as the NO3 specific ion electrode (SIE), may save time and costs, and reduce hazards. The objective of this study was to compare estimates of stalk NO3 concentration by FIA and NO3 SIE. For FIA, NO3 was extracted with 2 M KCl, and the extract was filtered before analysis. For SIE, NO3 was extracted with 0.04 M (NH4)2SO4, and the extract was analyzed without filtration. The slope of the linear regression between concentrations estimated by SIE and FIA did not differ from 1.0. Use of the NO3 SIE, compared with FIA, reduces costs, sample processing, and use of hazardous chemicals.

Abbreviations: FIA, flow-injection analysis • SIE, specific ion electrode

INTRODUCTION

THE END-OF-SEASON corn stalk NO3 test was proposed and advocated by Binford et al. (1990) as a method of determining if excessive or insufficient N was available to the corn crop during the latter part of the season. In the test, 20-cm segments of corn stalks (between 10 and 30 cm above the soil) are collected from several plants ({approx}10), dried, ground, and analyzed for NO3–N. Nitrate N concentrations less than about 700 mg kg-1 plant tissue indicate that available N limited grain yield; NO3–N concentrations above 2000 mg kg-1 indicate that excessive amounts of N were available to the crop (Binford et al., 1992). Other researchers have evaluated the proposed test and concur that when end-of-season stalk NO3 concentrations are great (>2000 mg kg-1), excessive levels of N were available to the crop (Varvel et al., 1997). These studies suggest that the end-of-season corn stalk NO3 test can be used as a postmortem to determine if yield-limiting or excessive N was present. Historical knowledge of crop N need may be used by producers to guide future fertilizer-N management, thereby improving profitability and reducing environmental degradation.

In the initial publications on use of the end-of-season stalk NO3 test, Binford et al. (1990, 1992) reported using the MgO–Devarda alloy steam-distillation procedure (Keeney and Nelson, 1982) and the Lachat1 flow-injection procedure (Lachat Instruments, Milwaukee; Method 12-107-04-1-B) to determine NO3 concentration in aliquots of filtered extracts prepared by shaking known weights of ground stalk material for 30 min in 100 mL of 2 M KCl. Though accurate, these analytical procedures are expensive, time-consuming, and employ hazardous chemicals (strong acids and bases and Cd).

Given that the goal of the stalk NO3 test is to determine if stalk NO3–N concentrations are less than 700 mg kg-1 or greater than 2000 mg kg-1, it seems logical that a somewhat less accurate procedure could provide essentially the same information, with the possibility of saving time and laboratory resources and avoiding safety and environmental hazard issues. A candidate procedure that is less expensive and less time-consuming, but may be less accurate, is the use of a NO3 SIE. The object of this study was to compare stalk NO3 concentration determined by the flow-injection method and NO3 SIE techniques.
Materials and methods
Shortly after physiological maturity, stalk samples were collected from 10 corn plants in a crop sequence x inbred line x N rate experiment initiated to determine the optimum rate of N fertilizer application for hybrid seed production fields (Wilhelm and Johnson, 1997). Twenty-two (Table 1) of these samples were selected for use in this study to compare methods of determining stalk NO3 concentration. Samples were selected a priori to represent the range of treatment combinations in the study, and therefore were assumed to provide samples covering the range of stalk NO3 concentrations found in producers' fields.
Stalk segments were 10 to 20 cm in length and came from the base of the stalk, from 0 to 25 cm above the soil surface. At sampling time, all plants in a 3.1-m segment of row were cut at the soil surface and moved to the field edge. Ten of these plants were selected at random and a stalk segment was taken from each. Each stalk segment was composed of one node and one internode (Fig. 1) . Individuals collecting the samples estimated the fraction of total length of internode between the lowest node and the cut end of the stalk on each sampled plant. The length of internode above the lowest node needed to represent the complement of the fraction below the node was estimated and the stalk cut at that point. In the example shown in Fig. 1, about 0.3 of the internode below the lowest node remained on the stalk as it was removed from the field. To collect the equivalent of one internode, 0.7 of the internode above the lowest node was estimated and the stalk cut at that point. In so doing, each stalk segment was composed of one node and one internode, but part of the internode portion of the sample came from the internode below the node and part from the internode above the node. This sampling procedure was used so that differences in NO3 concentration between node and internode tissue and differences in length of internodes would not influence estimates of the stalk NO3 concentration. Stalk segments were dried at about 60°C and ground with a Wiley mill to pass a 2-mm screen before extraction and NO3 analysis.

In this paper we will use the term FIA to mean the automated procedure for NO3 analysis defined by Lachat Instruments (Milwaukee, WI; Method 12-107-04-1-B). This procedure is a modification of the Griess–Ilosvay method (Keeney and Nelson, 1982). Nitrate was extracted by shaking a 0.25-g sample of ground stalk tissue for 30 min with 100 mL of 2 M KCl. Extraction media were filtered through Whatman No. 1 paper before analysis with the flow-injection procedure.

For the NO3 SIE method, 0.25 g of stalk tissue was shaken with 50 mL of 0.04 M (NH4)2SO4 for 30 min. This extraction medium was chosen because it is one of many possible weak salt solutions that could be used to extract NO3 from plant tissue and is the solution used in the outer chamber of the reference electrode. If water were used as the extraction medium, equal parts of extractant and 0.08 M (NH4)2SO4 would be combined to determine NO3 concentration with the NO3 SIE. By using 0.04 M (NH4)2SO4, the need to filter the media was also eliminated, because the electrode could be placed directly into the extraction medium to determine NO3 concentration. Reference and NO3 SIE (Orion Research, Boston) were placed directly into the agitating extraction media and electrometer readings observed. Readings were recorded after sequential additions of 1-mL aliquots of NO3 interference suppressor [0.0378 M (Al2SO4)3, 0.0109 M Ag2SO4, 0.0257 M H3SNO3, and 0.0210 M H3BO3] produced no change in meter output. Several ions can influence the accuracy of NO3 concentration estimates made with NO3 SIE. The NO3 interference suppressor was used to eliminate interference from organic anions (aluminum sulfate), halogens, cyanide and sulfide ions (silver sulfate), nitrite (sulfamic acid), and carbonate and bicarbonate ions (boric acid; Orion Research, 1980).

For both analytical methods, NO3–N concentration in stalk tissue was calculated from a standard curve (NO3–N on log scale) developed from known standards ranging in NO3–N concentration from 0 to 20 mg kg-1. For the FIA, standards were prepared in 2 M KCl; for the NO3 SIE, in 0.04 M (NH4)2SO4. Analysis of variance, regression analysis, and t-tests were used to determine if the two methods differed in their estimates of NO3 concentration and how the differences affected interpretation of the end-of-season stalk NO3 test.

Results and discussion
To be useful as an alternative method for assessing stalk NO3 concentration, the NO3 SIE method must have two characteristics. First, mean values must be similar to those found by methods assumed to be the standard (FIA). Secondly, estimates of NO3 concentration must be repeatable. We will address the second question first. Though we expected FIA to provide more precision than the NO3 SIE, mean standard deviations (3 extractions and analyses on each of 22 samples) for the two methods were similar; 37.5 mg NO3–N kg-1 for FIA and 44.3 mg NO3–N kg-1 for the NO3 SIE. Sample NO3–N concentrations ranged from about 100 to 5300 mg kg-1. These standard deviations values may seem large; however, when they were converted to coefficients of variation and expressed as percent of the mean, the precision of both methods was very acceptable (1.5% for FIA and 1.8% for NO3 SIE). Visual examination of the relationship between standard deviations and means (Fig. 2) appears to show a stronger association between these parameters for the NO3 SIE than for FIA. However, when linear correlation coefficients were computed the reverse was found: For the NO3 SIE method, ; for the FIA method, . This apparent contradiction was caused by the strong influence of five samples that showed very little variation with the NO3 SIE (i.e., the five points falling on the x-axis in Fig. 2). When these points were removed, results of the correlation analysis agreed with our visual assessment. The recalculated correlation coefficient for the NO3 SIE method was . The reason for several points having no variation is largely an artifact of the use of a digital electrometer to measure output from the NO3 SIE. The meter cannot display very small differences between samples. Therefore, the meter readout was the same for all samples and the variation was calculated to be zero. The purpose of the stalk NO3 test is to determine if NO3–N concentrations are less than 700 mg kg-1 or greater than 2000 mg kg-1. Therefore, the inability to detect small differences between samples and a strong correlation between the mean and standard deviation of measurements (undesirable characteristics for analytical procedures) have little bearing on the usefulness of the technique.

In conclusion, these data indicate that stalk NO3–N concentration estimated by the two methods may differ slightly. The strong relationship between results produced by the methods indicates that any discrepancy between methods would be small and within the requirements for the end-of-season stalk NO3 test. In addition, savings in terms of equipment costs and time for sample preparation could be substantial. Use of hazardous chemicals is also eliminated: There is no need for strong acids and bases, nor for the carcinogen Cd.



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